Marine Seismic Survey Systems and Methods Using Autonomously or Remotely Operated Vehicles

ABSTRACT

Systems and methods for carrying out seismic surveys and/or conducting permanent reservoir monitoring with autonomous or remote-controlled water vehicles, including surface and submersible vehicles, are described. Additional methods carried out by autonomous or remote-controlled water vehicles and associated with seismic surveys are further described.

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a continuation application of co-pending U.S. patent applicationSer. No. 13/209250 to Everhard Muijzert, et al., filed on Aug. 12, 2011,and entitled “Marine Seismic Survey Systems and Methods UsingAutonomously or Remotely Operated Vehicles,” which claims the benefit ofU.S. Provisional Patent Application Nos. 61/440,136, filed on Feb. 7,2011; 61/413,217, filed on Nov. 12, 2010; and 61/383,940, filed on Sep.17, 2010, all of which are hereby incorporated by reference in theirentirety.

TECHNICAL FIELD

The present disclosure relates in general to marine seismic dataacquisition, and more particularly to systems and methods for conductingseismic surveys and performing activities related to seismic surveysusing autonomously operated vehicles (AOVs) and/or remotely operatedvehicles (ROVs).

BACKGROUND

Seismic exploration involves surveying subterranean geologicalformations for hydrocarbon deposits. A seismic survey typically involvesdeploying seismic source(s) and seismic sensors at predeterminedlocations. The sources generate seismic waves, which propagate into thegeological formations creating pressure changes and vibrations alongtheir way. Changes in elastic properties of the geological formationscatter the seismic waves, changing their direction of propagation andother properties. Part of the energy emitted by the sources reaches theseismic sensors. Some seismic sensors are sensitive to pressure changes(hydrophones), others to particle motion (e.g., geophones), andindustrial surveys may deploy only one type of sensors or both. Inresponse to the detected seismic events, the sensors generate electricalsignals to produce seismic data. Analysis of the seismic data can thenindicate the presence or absence of probable locations of hydrocarbondeposits.

Marine seismic surveys may be carried out in a variety of manners. Forexample, towed array surveys are quite popular and involve the use ofone or more large vessels towing multiple seismic streamers and sources.Streamers can be over 10 km long and contain a large number of closelyspaced hydrophones and possibly also particle motion sensors, such asaccelerometers.

Another method for acquiring seismic data involves the deployment ofseismic nodes at the seafloor. Such nodes may contain a pressure sensor,a vertical geophone and two orthogonal horizontal geophones as well as adata recorder and battery pack. Nodes may be deployed by an ROV orsimply deployed off the back of a ship.

SUMMARY

The present disclosure is directed to the use of AOVs and/or ROVs forconducting seismic surveys and/or performing other activities related toseismic data acquisition. Exemplary AOVs and/or ROVs that may be used incarrying out the principles of the present disclosure are alreadyavailable in the marketplace and may include one or more of thefollowing: the wave glider® provided by Liquid Robotics, Inc. andfurther described in U.S. Pat. No. 7,371,136, which is herebyincorporated by reference, the Slocum™ diver provided by Teledyne WebbResearch and further described athttp://www.webbresearh.com/slocumglider.aspx, and the uRaptor™ Twin TVCUAV provided by Goscience and further described athttp://www.goscience.co.uk/index.html.

The AOVs and/or ROVs contemplated within the present disclosure may beoutfitted with a seismic streamer carrying one or more seismic sensors.Such sensors may include pressure sensors, e.g., hydrophones, andparticle motion sensors, such as accelerometers. The streamer may bedeployed in a conventional manner and thus towed horizontally throughthe water column, or in some embodiments, the streamer may dependvertically through the water column. The AOVs and/or ROVs and associatedstreamers may be used for permanent reservoir monitoring.

In addition to conducting seismic surveys, the AOVs and/or ROVs may beused to carry out other activities related to the acquisition of seismicdata. For example, the AOVs and/or ROVs may be utilized to take currentmeasurements, to position seismic survey equipment, to perform soundverification studies and/or monitor the presence of marine mammals.

The foregoing has outlined some of the features and technical advantagesof the present disclosure in order that the detailed description thatfollows may be better understood.

Additional features and advantages of the present disclosure will bedescribed hereinafter which form the subject of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other features and aspects of the present disclosurewill be best understood with reference to the following detaileddescription of a specific embodiment of the invention, when read inconjunction with the accompanying drawings, wherein:

FIG. 1 is a schematic diagram of a marine seismic data acquisitionsystem according to an embodiment of the disclosure;

FIG. 2 is a flowchart depicting a method for performing a seismic surveyaccording to an embodiment of the disclosure;

FIGS. 3A-3D are schematic diagrams of seismic survey arrangementsaccording to embodiments of the disclosure;

FIG. 4 is a schematic diagram of yet another seismic survey arrangementaccording to an embodiment of the disclosure;

FIG. 5 is a schematic diagram of yet another seismic survey arrangementaccording to an embodiment of the disclosure; and

FIG. 6 is a schematic diagram of a permanent reservoir monitoringarrangement according to an embodiment of the disclosure.

DETAILED DESCRIPTION

Refer now to the drawings wherein depicted elements are not necessarilyshown to scale and wherein like or similar elements are designated bythe same reference numeral through the several views.

Referring to FIG. 1, a water vehicle 10 may take the form of an AOV orROV. In some embodiments, the water vehicle 10 may be adapted to descendthrough the water column, while in other embodiments, the water vehiclemay be adapted only for use on the sea surface. In the embodimentdepicted in FIG. 1, the vehicle 10 takes the form of a wave glider,which harnesses wave energy to impart motion to the glider. Additionaldetails regarding operation of the wave glider are disclosed in U.S.Pat. No. 7,371,136, which is incorporated herein by reference. Accordingto principles of the present disclosure, the wave glider platform may beused for seismic surveying and thus is instrumented with at least oneseismic sensor 12. The sensor 12 may be located on the wave glider, ortowed behind it with a tether, or inside a hydrodynamic body coupled tothe wave glider, such as a streamer 14. In the embodiment depicted inFIG. 1, the streamer 14 may depend in a substantially vertical mannerfrom the wave glider into the water column. In other embodiments, thestreamer 14 may be substantially horizontal within the water column,while in still other embodiments, the streamer may take on a slanted orundulating configuration. The streamer 14 is preferably shorter thanconventional streamers.

In accordance with embodiments of the disclosure, the seismic sensors 12may be pressure sensors only, particle motion sensors only, or may bemulti-component seismic sensors. For the case of multi-component seismicsensors, the sensors are capable of detecting a pressure wavefield andat least one component of a particle motion that is associated withacoustic signals that are proximate to the multi-component seismicsensor. Examples of particle motions include one or more components of aparticle displacement, one or more components (inline (x), crossline (y)and vertical (z) components) of a particle velocity and one or morecomponents of a particle acceleration.

Depending on the particular embodiment of the disclosure, themulti-component seismic sensors may include one or more geophones,hydrophones, particle displacement sensors, optical sensors, particlevelocity sensors, accelerometers, pressure gradient sensors, orcombinations thereof. For example, in accordance with some embodimentsof the disclosure, a particular multi-component seismic sensor mayinclude three orthogonally-aligned accelerometers (e.g., athree-component micro electro-mechanical system (MEMS) accelerometer) tomeasure three corresponding orthogonal components of particle velocityand/or acceleration near the seismic sensor. In such embodiments, theMEMS-based sensor may be a capacitive MEMS-based sensor of the typedescribed in co-pending U.S. patent application Ser. No. 12/268,064,which is incorporated herein by reference. Of course, other MEMS-basedsensors may be used according to the present disclosure. In someembodiments, a hydrophone for measuring pressure may also be used withthe three-component MEMS described herein.

It is noted that the multi-component seismic sensor may be implementedas a single device or may be implemented as a plurality of devices,depending on the particular embodiment of the disclosure. A particularmulti-component seismic sensor may also include pressure gradientsensors, which constitute another type of particle motion sensors. Eachpressure gradient sensor measures the change in the pressure wavefieldat a particular point with respect to a particular direction. Forexample, one of the pressure gradient sensors may acquire seismic dataindicative of, at a particular point, the partial derivative of thepressure wavefield with respect to the crossline direction, and anotherone of the pressure gradient sensors may acquire, at a particular point,seismic data indicative of the pressure data with respect to the inlinedirection.

In the embodiment of FIG. 1, the streamer 14 takes the form of avertical cable, i.e., a streamer that extends substantially verticallythrough the water column. See, e.g., U.S. Pat. No. 4,694,435, which isincorporated herein by reference. In this embodiment, the water vehicle10 may maintain a stationary position while recording seismic data viathe seismic sensors 12. The position of the water vehicle 10 may begeographically stationary or, alternatively, the water vehicle and thecable 14 may drift with the currents. The length of the vertical cable14 may vary between less than a meter to over a kilometer. Verticalcables may be much thinner than conventional towed streamers, thusfacilitating ease of handling. The vertical cables 14 of the presentdisclosure may be modified in various manners to improve performance.For example, fairings 16 may be employed to reduce cross-flow noise dueto currents and drag. Also, the vertical cables 14 may be formed offiber optic cables and/or cables with fiber optic sensors may beemployed, thus resulting in a lighter and thinner cable relative toconventional streamer cables. Still further, accelerometers capable ofmeasuring the gravity vector may be used to measure the tilt of thestreamer 14 relative to the vertical.

In practice, the water vehicle 10 may be deployed to a desired positionfor seismic surveying. Upon positioning, a seismic source 18 may bedetonated to generate acoustic waves 20 that propagate through an oceanbottom surface 22 and into strata 24, 26 beneath the ocean bottomsurface. The seismic source 18 may depend from another water vehicle 10(as shown in FIG. 1), or more conventional source deployments may beused, such as the use of dedicated source vessels. The acoustic signals20 are reflected from various subterranean geological formations, suchas an exemplary formation 28 depicted in FIG. 1. The incident acousticsignals 20 produce corresponding reflected acoustic signals, or pressurewaves 30, which are sensed by the seismic sensors 12. The seismicsensors 12 generate signals (digital signals, for example), called“traces,” which indicate the acquired measurements of the pressurewavefield and particle motion (if the sensors include particle motionsensors). The traces are recorded and may be passed to a signalprocessing unit 32 disposed on the water vehicle 10. Of course, thesignal processing unit 32 may be disposed on another vesselparticipating in the survey. The signal processing unit 32 may include adigitizer and memory for storing seismic data acquired during thesurvey. The water vehicle 10 may further include an onboardcommunication unit 34, which may communicate with a base station locatedonshore or at sea, such as on a rig or vessel. The communication unit 34may be used to transmit water vehicle position, quality controlparameters, time information and seismic data. The communication unit 34may also send or receive commands particular to the seismic survey. Suchcommands may include redirecting the water vehicles 10 for purposes ofinfill.

Once sufficient data has been collected for a particular position, thewater vehicle 10 may be instructed to then move to a new surveyposition. The rapid deployment and re-deployment enabled through use ofthe water vehicle provides efficiency gains in acquiring seismic data.In some embodiments, the water vehicles 10 may be launched from aseismic source vessel, which tows one or more gun arrays for generatingseismic signals. Referring to FIG. 2, a workflow 40 for conducting aseismic survey includes the steps of: launching and positioning of watervehicles in a survey region 42; positioning the source vessel 44;starting a seismic survey 46; recording seismic data 48; ending theseismic survey 50; and retrieving the water vehicles 52.

Several seismic survey geometries may be employed via the workflow usingthe water vehicles 10 as seismic data acquisition platforms. Forexample, FIG. 3A depicts a survey geometry in which the water vehicles10 advance along a substantially linear path, while a source vessel 60shoots along a sail pattern that is substantially perpendicular to thepaths of the water vehicles. It is to be appreciated that in practice,the water vehicles 10 do not travel along a substantially linear path,but rather there is likely some deviation from the linear path. Thewater vehicles 10 preferably have spacing similar to towed streamers,such as 100 meter intervals in the crossline direction. The watervehicles 10 may move at a speed (e.g., 1 knot or less) considerablydifferent from the source vessel (e.g., 5 knots or more). This not onlyfacilitates the survey geometry, but also allows the smaller watervehicles 10 to conserve more fuel relative to the faster and largersource vessel 60. When the source vessel 60 has reached a boundary ofthe area under survey, it may turn around and continue shooting along aline perpendicular to the water vehicles' 10 sail direction.

FIG. 3B illustrates another possible geometry in which the watervehicles 10 advance along a substantially linear path, while the sourcevessel 60 shoots along a path either perpendicular or generallytransverse to the water vehicles' path. FIG. 3C illustrates yet anotherpossible geometry in which the source vessel 40 shoots along a pathsubstantially parallel to the path of the water vehicles 10. FIG. 3Dillustrates another geometry in which the source vessel 60 shoots in asubstantially circular configuration in and around a survey area of thewater vehicles 10. Elliptical configurations are also contemplated. Atthe conclusion of the seismic survey, the source vessel 40 may collectthe water vehicles 10 to permit data retrieval and recharging of thewater vehicles, if necessary.

To facilitate seismic surveying, the water vehicles 10 may have anonboard positioning system. This may include conventional GPS systemsfor surface units and/or short base line acoustic positioning systemsfor positioning the streamer 14 (FIG. 1) relative to the water vehicle10. Other positioning systems may utilize one or more compasses with orwithout accelerometers to determine streamer shape and location relativeto the water vehicle 10.

Multiple AUV's may employ relative positioning methods such as RTK oracoustic distance measuring systems. Radar positioning methods mightalso be used, with a master vessel or platform using micro-radar systemsfor locating one or more gliders relative to its known positing.

Referring to FIG. 4, in some embodiments, the water vehicles 10 may bedeployed together with a conventional towed array seismic survey system70 in which conventional seismic streamers 72 are towed through thewater column to collect seismic data. In such embodiments, the watervehicles 10 may provide support by collecting and providing data usefulfor facilitating operation of the seismic survey. For example, the watervehicles 10 may be used for measuring current in real time using an ADCPor other current measurement device, or alternatively comparing itsspeed over ground to a water speed measurement. Such current data may betransmitted to a conventional survey vessel 74 (e.g., via communicationunit 32 (FIG. 1)) operating in the area to allow the vessel toanticipate the current velocity it might encounter while traversing downa survey line. Knowledge of the current ahead can be used to control thevessel speed and rudder, and streamer and source steering devices,allowing a smooth transition from one current regime to the next.

The water vehicles 10 according to the present disclosure may also beused with conventional towed arrays to aid in positioning of thestreamers 72. In such embodiments, the water vehicles 10 may provide oneor more Global Navigation Satellite Systems (GNSS) Earth Centered EarthFixed (ECEF) reference points. For example, the water vehicles 10 may beequipped with GPS devices. The deployed streamers 72 may be equippedwith acoustic positioning systems, such as the IRMA system described inU.S. Pat. No. 5,668,775, which is hereby incorporated by reference.Sensors in or on the streamers may be positioned with respect to a shortbaseline (sbl) or ultra short baseline (usbl) transducer head mounted onthe wave glider platform with reference to the GNSS antenna. To furtherimprove the position accuracy of the streamers 72, the water vehicles 10in the survey area may become part of the acoustic positioning system.In this regard, the water vehicles 10 may record the acoustic signalsemitted by the acoustic sources in the streamers 72 and transmit thoserecordings to the vessel 74. The water vehicles 10 may also carryadditional acoustic sources whose signals are recorded by the streamers72. The recorded acoustic signals from the streamers 72 and the watervehicles 10 may then be combined and used to determine an even moreaccurate position of the streamers and the water vehicles. In someembodiments, the water vehicles 10 may be deployed within the spread ofstreamers 72 if risk of entanglement is low. Otherwise the watervehicles may sail outside the streamer spread as illustrated in FIG. 4.

Referring to FIG. 5, in some embodiments, the water vehicles 10 may bedeployed in conjunction with a 2D seismic survey in which only onestreamer 72 is towed behind the vessel 74. In such surveys, obtainingaccurate position information is more challenging. Prior art solutionsinvolve measuring the streamer orientation at regular intervals usingcompasses inside the streamer. According to the principles of thepresent disclosure, the water vehicles 10 may be deployed with acousticpositioning equipment as previously described and at a position offsetfrom the sail line of the streamer 72. The acoustic positioningequipment on the water vehicles 10 is able to both receive and transmitacoustic signals. Accordingly, methods of triangulation may be used toaccurately determine streamer position and shape. This more accuratestreamer position information may be used to determine the furthercourse of the vessel and streamer and for correcting to such position.The streamer 72 may also be fitted with steerable birds that whencombined with new position information would allow for more accuratepositioning of the streamer in response to currents and feathering.

In still other embodiments, and with reference to FIG. 6, one or morewater vehicles 10 may be deployed in the vicinity of a known oil and/orgas reservoir 100 and associated drilling rig 102 for the purposes ofmonitoring the reservoir. Reservoir monitoring is a common practice inthe oilfield industry to assess the continued viability of thereservoir. However, conventional towed array systems are ill-equipped toprovide reservoir monitoring as the length and size of such spreads caninterfere with the drilling rig and associated supply vessels operatingin the area. According to the principles of the present disclosure,several water vehicles 10 may be deployed with associated mini-streamers14. Such vehicles 10 allow for closer deployment to the survey region ofinterest (e.g., reservoir 100) and also reduce risks associated withstreamer entanglement. Indeed, in embodiments where the water vehicles10 are designed to ascend and descend within the water column, risk ofentanglement or collision with the rig 102 and/or supply vessels may befurther mitigated.

Also, a combination of surface vehicles 10 and underwater vehicles 10may be simultaneously deployed for the purposes of permanent reservoirmonitoring. For example, the surface vehicles 10 may be deployed in avertical cable arrangement as shown in FIG. 1, while the underwatervehicles 10 may provide infill coverage complementary to the surfacevehicles. In such embodiments, the underwater vehicles 10 may towstreamers in a substantially horizontal direction, or the seismicsensors may be coupled to the underwater vehicle itself, thuseliminating the need for streamers. Of course, other complementarygeometries are contemplated, such as using the surface vehicles 10 totow substantially horizontal streamers, while the underwater vehicles 10record seismic data (with or without streamers) in a substantiallyvertical direction in the water column.

The vehicles 10 may be deployed in conjunction with an energy sourcethat provides useful data for seismic purposes. For example, such anenergy source may include a seismic source (e.g., seismic source 18 inFIG. 1), drilling induced acoustic pressure waves, or production inducedacoustic pressure waves such as might result from water or gasinjection. In embodiments where seismic sources are deployed with thewater vehicles 10, the seismic source may be a conventional air gun,marine vibrator, or non-traditional environmentally friendly source.Marine vibrators and non-conventional environmentally friendly sourcesare characterized in that they have a lower amplitude than conventionalairguns. The seismic sensors towed by, or otherwise coupled to, thewater vehicles 10 are better suited for recording lower amplitudes dueto the low water relative speeds of the water vehicles that avoid thewater flow induced pressure waves that impact the hydrophones ofconventional towed array systems. Further, the water vehicles 10 arebetter suited for recording the lower amplitude drilling and productioninduced noise produced in the vicinity of the reservoir 100. Thecombination of the relatively quiet towing platform of the watervehicles 10 and seismic signal emission without the need for a sourcetowing vessel is a significant efficiency gain for reservoir monitoring.Such seismic monitoring could be performed continuously during the lifeof the reservoir to calibrate reservoir models and generally giveinformation that will increase production.

In some embodiments, the water vehicle 10 may be used to monitor thepresence of marine mammals in an area where seismic source signals arebeing generated. The hydrophones 12 towed by the water vehicles 10 maybe used to record data in two separate sampling frequencies—one being asurvey sampling frequency associated with acoustic signals emitted bythe seismic source, and the other being a detection sampling frequencyassociated with marine mammal vocalizations. Additional detailsregarding such a marine mammal detection system are further described inU.S. Patent Publication No. 2010/0067326, which is hereby incorporatedby reference. In other embodiments, the water vehicles 10 and associatedmini-streamers 14 may be dedicated to marine mammal monitoring and thusthe sensors 12 are designed for and used exclusively to detect marinemammal vocalizations. In still other embodiments, the streamers containsensors designed for seismic signal recording and additional speciallydesigned marine mammal sensing devices together.

In still other embodiments, the water vehicles 10 may be deployed toengage in sound verification studies to assess the zone of impactassociated with firing of seismic sources during the survey. Suchstudies are typically performed prior to the start of a seismic surveyand are aimed at calculating a zone of impact based on numerical modelsfor the survey area, including water depth, ocean bottom properties andwater properties. By assessing the zone of impact, the area may becleared prior to beginning the seismic survey. The assessed zone ofimpact may be verified by shooting a line into an array of hydrophonesdisposed substantially perpendicular to the shooting line. Thus,measurements at different offsets may provide the desired verification.The array of hydrophones may be deployed via the water vehicles 10, thusobviating the need for deploying more costly chase and/or supply vesselsto perform the sound verification studies. Moreover, given therelatively small surface area of the water vehicles 10, suchverification studies may be performed in real time, thus avoiding delaysof the start of the seismic survey.

Although specific embodiments of the invention have been disclosedherein in some detail, this has been done solely for the purposes ofdescribing various features and aspects of the invention, and is notintended to be limiting with respect to the scope of the invention. Itis therefore contemplated that various substitutions, alterations,and/or modifications, including but not limited to those implementationvariations which may have been suggested herein, may be made to thedisclosed embodiments without departing from the spirit and scope of theinvention as defined by the appended claims which follow.

What is claimed is:
 1. A method of seismic surveying, comprising:deploying a plurality of unmanned water vehicles in a region forsurveying, the unmanned water vehicles comprising one or more autonomousor remotely controlled surface and/or underwater vehicles, at least oneof such unmanned vehicles having motion dependent primarily onharvesting wave energy; and coupling at least one hydrodynamic body toone or more of the unmanned water vehicles, the hydrodynamic body havinga sensor for recording seismic data.
 2. A method according to claim 1,further comprising deploying a source to generate seismic signals, thesource being coupled to one of the unmanned water vehicles.
 3. A methodaccording to claim 1, wherein deploying a plurality of unmanned watervehicles further comprises deploying a plurality of unmanned surfacevehicles and deploying a plurality of underwater vehicles, one or moreof such unmanned surface and underwater vehicles having a seismic sensorcoupled thereto.
 4. A method according to claim 3, wherein one or moreof the unmanned surface vehicles has a streamer coupled thereto, andfurther comprising deploying the streamer in a generally verticaldirection through the water column.
 5. A method according to claim 4,wherein one or more of the unmanned underwater vehicles has a streamercoupled thereto, and further comprising towing the streamers coupled tothe underwater vehicles in a generally horizontal direction through thewater column.
 6. A method according to claim 4, wherein one or moreseismic sensors is coupled to the unmanned underwater vehicles, andfurther comprising maneuvering the unmanned underwater vehicles in agenerally horizontal direction through the water column.
 7. A methodaccording to claim 3, wherein one or more of the unmanned surfacevehicles has a streamer coupled thereto, and further comprisingdeploying the streamer in a generally horizontal direction through thewater column.
 8. A method according to claim 7, wherein one or more ofthe unmanned underwater vehicles has a streamer coupled thereto, andfurther comprising towing the streamers coupled to the unmannedunderwater vehicles in a generally vertical direction through the watercolumn.
 9. A method according to claim 7, wherein one or more seismicsensors is coupled to the unmanned underwater vehicles, and furthercomprising maneuvering the unmanned underwater vehicles in a generallyvertical direction through the water column.
 10. A method of seismicsurveying, comprising: towing one or more seismic streamers with a towvessel, the one or more seismic streamers having seismic sensors coupledthereto for recording seismic data; deploying one or more unmanned watervehicles in an area generally proximate to the seismic streamers, theunmanned water vehicles comprising one or more autonomous or remotelycontrolled unmanned surface and/or underwater vehicles, at least one ofsuch vehicles having motion dependent primarily on harvesting waveenergy; and using the unmanned water vehicles to support the seismicsurvey.
 11. A method according to claim 10, wherein using the unmannedwater vehicles to support the seismic survey comprises using theunmanned water vehicles to measure current in the survey region.
 12. Amethod according to claim 11, further comprising transmitting themeasured current to the tow vessel.
 13. A method according to claim 10,wherein using the unmanned water vehicles to support the seismic surveycomprises using the unmanned water vehicles to position the one or morestreamers.
 14. A method according to claim 13, further comprising usingthe unmanned water vehicles to record acoustic signals transmitted fromthe streamers, and further transmitting such acoustic signals to the towvessel.
 15. A method of seismic surveying, comprising: deploying one ormore unmanned water vehicles in a seismic survey area, the unmannedwater vehicles comprising one or more autonomous or remotely controlledunmanned surface and/or underwater vehicles, wherein the unmanned watervehicles have one or more seismic sensors coupled thereto, at least oneof such unmanned vehicles having motion dependent primarily onharvesting wave energy; deploying one or more source vessels in theseismic survey area, the source vessel having one or more sourcescoupled thereto; advancing the unmanned water vehicles along apredetermined path; advancing the source vessel along a predeterminedpath; emitting acoustic signals from the one or more sources to generateseismic data; and recording the seismic data via the seismic sensorscoupled to the unmanned water vehicles.
 16. A method according to claim15, wherein the unmanned water vehicles advance along a substantiallylinear path and the source vessel advances along a path substantiallyperpendicular to the path of the water vehicles.
 17. A method accordingto claim 15, wherein the unmanned water vehicles advance along asubstantially linear path and the source vessel advances along a pathsubstantially parallel to the path of the water vehicles.
 18. A methodaccording to claim 15, wherein the unmanned water vehicles advance alonga substantially linear path and the source vessel advances along a pathsubstantially transverse to the path of the water vehicles.
 19. A methodaccording to claim 15, wherein the unmanned water vehicles advance alonga substantially linear path and the source vessel advances along asubstantially circular or elliptical path in the survey area.
 20. Amethod according to claim 15, wherein the unmanned water vehiclesadvance at a first velocity and the source vessel advances at a secondvelocity, the first velocity being less than the second velocity.
 21. Amethod according to claim 15, wherein the seismic sensors are disposedin a hydrodynamic body coupled to the unmanned water vehicles.